NO963931L - Method for testing the operation of a network element in a transmission network - Google Patents

Description

The present invention relates generally to the testing and diagnosis of transmission equipment, and more specifically to the testing of a network element operating at a transmission network realized by means of synchronous digital hierarchy (SDH) to determine whether its components are operating correctly. A network element is here meant a network element defined in the ITU specifications (International Telecommunication Union) such as e.g. can be a terminal multiplexer, a digital crossover switch, a so-called ADD/Drop multiplexer or a regenerator.

In order to standardize and improve digital transmission on land lines, the so-called synchronous digital hierarchy was developed and intended to be successful in a so-called plesiosynchronous system, where the synchronous digital hierarchy as a concept first of all means in principle that all nodes of a digital transmission network are synchronized with same clock and, secondly, that sent information is arranged in frames defined at several levels in accordance with the hierarchical order. The ITU Recommendation G.703, G.70X (draft) and G.781 - G.784 contain essential definitions with regard to the device's functions. The frames for sent information are called STM-N frames, where STM is short for "synchronous transport module" and N refers to the number in the hierarchy level so that lower levels have a lower number. At the lowest hierarchy level, the frame is STM-1 frames, and they are used to pack information, for example, in current PCM systems (pulse code modulation) of 2 Mbit/s, 8 Mbit/s and 34 Mbit/s. The transmission rate of the higher hierarchy levels is a multiple of the rate of the lowest level so that the number N in the name of the frame indicates the multiple of the transmission rate compared to the base rate.

From a received frame, it must be possible to sort out where the relevant sent information or payload begins. The frame therefore contains a pointer which is a number that defines the payload phase in the frame. The pointer points to the byte in the STM-N frame where the payload begins. Non-payload information includes pointers and overhead, which are used to control data transmission, to define the contents of the frame, and to detect and correct errors. The term "payload" does not refer to any specific data structure, but is used as a general expression for information with content not relevant for the control of data transmission.

Between the transmitting device and the receiving device, the information sent in the SDH network passes through specific transmission equipment or hubs. The entire transmission route from the device that assembles the frames to the device that takes the frames apart is called a path, as the definition is linked to the frame hierarchy so that if the information is packed in STM-4 frames on only part of the transmission path, this part is called an STM-4 level path. An STM-1 level path covers the entire transmission path using synchronous digital hierarchy from the transmitting device to the receiving device. The section of the transmission path between two transmission devices, which is capable of performing multiplexing, is called a multiplex section (MS), and a section with a transmission path between such devices, which only regenerates (amplifies) the signal without changing its multiplexing is called a regenerator section

(RS).

The information structure part that is sent between the devices and used to adjust the path and voltage levels is called administrative unit (AU). It includes the payload or a virtual container (VC) and an AU pointer indicating the phase difference between the payload and the STM-N frame. The AU pointer has a predetermined position in the STM-N frame (cf. fig. 1). One or more administrative units (AU) with a fixed position in the STM-N payload form an administrative unit group (AUG).

The above virtual container or VC frame is a component used in multiplexing to support the connections at the path level. A particular VC frame is sent intact from the beginning to the end of the respective path, in other words its content does not change between the transmitting device and the receiving device in the path. This includes payload and path overhead (POH).

A subordinate unit (TU) forms a connection between a lower and higher hierarchy level. It includes the payload or VC frame and a pointer indicating the position of the payload in the TU frame. The administrative unit (AU) differs from the subordinate unit (TU) in that the AU is a unit that can be cross-connected in the network and can thus be transmitted between different STM-1 signals, but the TU is an internal unit to a specific frame which cannot be transferred between different STM-1 signals without an administrative unit of a higher level. One or more sub-units (TU), which have a fixed position at a higher level VC frame, form a sub-unit group (TUG) which is formed by multiplexing TUs. A group can include subordinate units of different sizes.

A container (C) is the synchronized payload part of each VC. It includes a payload signal with a frequency that can be adjusted, if necessary, so that it is synchronized with the corresponding STM-1 signal. In the future, the container can also be a broadband signal.

The container (C), the virtual containers VC and the subordinate units (TU) may be formed on the basis of different base channel rates. The basic channel speed of 1.5 Mbit/s is used in the USA, Canada and Japan, and otherwise the speed of 2 Mbit/s is used. It is expressed in the name of the data structure so that the letter symbol is followed by two digits, where the first refers to the hierarchy level and the second, which can be 1 (=1.5 Mbit/s) or 2 (=2 Mbit/s), refers to the base channel rate. The term TU-12 means e.g. a subordinate unit of the first hierarchy level formed by a signal sent at the base channel rate of 2 Mbit/s.

The devices that take part in the communication or the so-called network elements in the SDH network are, among other things, terminal multiplexers, digital cross-connection switches, so-called ADD/Drop multiplexers and regenerators, which represent known technology in and of themselves. To realize data transmission, STM-N frames are assembled and disassembled in a multiplexer device using different hierarchy levels. Cross-connect switches form a connection between different input and output ports, i.e. they change the order and structure of the multiplexed components into signals directed to different output ports. A regenerator does not affect the content of the signal, but compensates for losses and other destructive effects occurring in the transmission path by amplifying the signal and removing interference.

The network elements consist of electronic components, which may present errors and functional difficulties due to material, composition or environmental conditions. The primary purposes are generally that sent information is correctly transferred from the input port to the output port of the network element. If the information is corrupt, the first goal is to detect errors and to a certain extent also to correct these so that information is sent in a satisfactory manner regardless of errors. Another purpose must be that the operator who is responsible for the network conditions and the communication can, when necessary, locate the network point causing the disturbance so that the corresponding device or component can be repaired or replaced.

Fig. 2 schematically shows an SDH network element 1 including an input port 2 and an output port 3. The network element 1 includes an input section 4, where the input signal is received and processed so that it can, for example, be cross-connected in essentially identical switch blocks 5a and/or 5b connected in parallel in the network element. The use of two identical switch blocks constitutes a so-called redundancy, whereby the signals can be routed through the secondary switch block if the switch block in the primary circuit is destroyed. Further network elements include an output section, where the signals are processed for transmission to the next network element 7 and then sent. The schematic fig. 2 shows only an example and shall not act as a limitation on what is described below. The present invention can also be used in connection with other network elements, of which are mentioned as examples elements that include several input and output ports, or an embodiment that includes several parallel and successive blocks inserted into a single parallel block 5a and 5b. The figure schematically also shows the microprocessor 8, which controls the operation of the network element.

Certain functions have been defined at the hierarchy level of the SDH system to detect errors occurring in transmission information. When data is sent, e.g. as STM-N frames over multiplex sections, then for each frame a bit of interleaved parity (BIP) verification is calculated using a polynomial of 24xN order, whereby the verification is a specific binary number. This procedure represents a certain special case when using CRC codes (cyclic redundancy check) and is called the BIP-24N procedure after the size and order of the polynomial. The calculated checksum from the frame was added to the overhead part, whereby previous verifications were included in the bit protected by the code when the BIP verification is calculated for the current frame. A BIP-8 procedure was used for transmission over a regenerator section whereby an eighth-order polynomial is used when the parity checksum is calculated. Virtual containers are similarly protected so that the protection of VC-4 and VC-3 containers uses the BIP-8 procedure and VC-2, VC-12 and VC-11 containers protected with a BIP-2 procedure.

The above-described device for detecting transmission errors is not as such suitable for examining the operation of a particular network element due to the fact that even if the parity information (BIP checksum) was examined at the output section 6 of a network element according to fig. 2, any error found will not indicate where it was generated in the switch block 5a or 5b used in the network element or in a previous transmission device on the same path. The signal can be routed through both the switch block 5a, 5b and statistically calculated if a failure has occurred on a long-term basis, which would give an indication of which switch block 5a, 5b operates best, but this takes time, and such a method is not reliable due to its statistical nature.

A procedure is known from Finnish patent publication Fl 925481 where a test byte is added to sent information in the input section of the network element, whereby the transmission of the test byte is the basis for examining the network element's operation. Once a test byte has been propagated through the network element along with transmitted information, it is detected at the output section of the network element and compared to original bytes to determine if the byte content has been changed. It is suggested that the test byte can be placed in the send information in any position where there is empty space, e.g. due to the removal of section and track overhead. Furthermore, it is suggested that the test byte fits with a certain predetermined bit pattern, which can also be changed, e.g. such as frequencies 11111111 - 10101010 - 01010101 - 00000000, to detect reflection and jamming errors.

Using an independent byte for testing purposes has the disadvantage that this procedure covers only the interval during which the byte propagates through the network element. Due to the fact that a frame includes several thousand bytes, it is difficult to detect an error that causes a single byte error, e.g. every 20 or every 100 bytes on average. Also, the use of test bytes only describes errors in the specific signal path along which the byte passes through the network element. Allocating a whole byte for testing purposes is also an inflexible method.

From WO 94/17614 a method is known which also uses a whole byte to test the operation of a network element part. In this case, the byte can be divided into fields, which contain location data for the circuit boards processing transmission information, and a parity switch calculated on the basis of transmission information, where the bit is set to zero or one, depending on which produces an equal total parity of transmitted frame or multiframe. In the case of TU-3/AU-4 frames, the test byte is placed in the area of the section overhead and in the case of lower hierarchy level TU 1/2 frames in the V4 byte of the corresponding path overhead. In addition to using a whole byte, this method has a disadvantage in that certain bits of the test byte are fixed zeros so that it becomes difficult to detect jamming errors in the path of these bytes. When using a single parity bit, only such error states are detected where an unequal number of bit errors are within the network element. Locating test bytes in the SOH area requires that the corresponding part of the section overhead and especially the test byte related to the VC frame must be connected in the network element via the same path and in the same phase as the relevant VC frame. The relevant SOH bytes received from the line cannot be transported in the device and the internal transmission paths cannot be serial STM-1 paths because, according to the above-mentioned publication, the test byte is placed above the so-called frame device bytes or above other SOH bytes. The method described in the above-mentioned publication can thus limit the internal realization of the network element.

The purpose of the present invention is to provide a method by which it is possible to provide a thorough and reliable examination of the operation of a network element in a digital transmission network. An object of the present invention is to provide a method where it is possible to make a quick and reliable decision with regard to which function block in the network element is to be used when it is initially damaged. An object of the invention is also to provide a method by which a faulty network element or a part of it can be quickly and reliably located in order to take corrective measures. An object of the invention is also to provide a transmission network element where the method according to the present invention is used.

The purpose of the present invention is provided by a device where a key signal is added to the transmission information in a certain first section of the network element, whereby the test signal is at least partially formed on the basis of the content of a certain information part and a certain second section of the network element with respect to the test signal is examined to determine whether errors have been introduced into the transmission information in the network element.

The method according to the present invention is characterized in that verification data is added to the sending information in a certain first section of the network element, whereby verification data is at least in part formed on the basis of the content of sending information frames and that verification data is read in a certain second section of the network element to find whether the components in the network element between the first part and the second part are operating correctly.

An object of the invention is also a device for realizing the method according to the invention. The device includes a first section, a second section and a device for transferring information between them and is characterized in that the first section includes information generating devices for generating verification data based on the content of sent information, which has been received and an adding device for adding the verification data to sent information and that the second section includes an interpretation device for interpreting the verification data to determine whether the device that sends information between the first and second sections is operating correctly.

Above, a calculation and coding procedure was described which belongs to the basic functions of the SDH transmission system defined in the above-mentioned ITU recommendation. According to the invention, an efficient procedure is provided for monitoring transmission errors in a network element so that first the information about parity errors observed in the relevant signal to be sent is added to the signal in a certain section of the network element, preferably in its input section. The parity of each frame is calculated in this section of the network element and the parities are compared with the original parity bits that are added to the relevant information when the frames are formed. As a result of the comparison, a number of parity errors observed for each frame is provided, and this number is added as a binary number to a certain one of the free positions contained in the transmitted information. In some other section of the network element, preferably in the output section, the parity is recalculated for each frame and the parities are compared with the original parity bits. As a result of this comparison, the observed number of parity errors in the information, which has passed through the network element to be examined, is provided for each frame. When this result is compared with a number of parity errors calculated in the input section, the number of parity errors occurring within the network element is provided as a result. The number of parity errors calculated in the input section can be read out by the output section due to the fact that what was described above was added in a certain free position to sent information.

In addition to the test signal representing the number of parity errors, an advantageous embodiment of the present invention ensures that the test bits are assigned to the other certain free position in transmitted information, so that the passage of test bits through the network element provides information about the general operation of the transmission path and so that they also can act as a synchronization signal that provides a correctly read information about the number of parity errors. As test bits, it is possible to use bits that change in accordance with a certain sequence, and the position of the test bits in the frame can be changed so that they provide broad information about the operation of the blocks that take part in the transmission of the information. It is also possible to shift the positions of the test bits and the bits representing the number of observed errors in different frames, and the bits can be inverted (zeros to ones and vice versa) according to a certain predetermined timing program, which makes the test more versatile.

In what follows, the invention will be described in more detail using preferred embodiments, shown as examples, and with reference to the drawings, where:

Fig. 1 shows the known structure of an STM-N frame.

Fig. 2 schematically shows the known structure of a network element.

Fig. 3 shows the mutual localization of test bits ob bits that represent

parity error in a preferred embodiment of the invention.

Fig. 4 shows a mutual localization of test bits and bits representing parity errors

in another preferred embodiment of the invention.

Fig. 5 shows a block diagram of a network element according to the present invention.

The same reference numbers are used for corresponding parts in the figures.

It is previously known that when a signal to be sent in the SDH system arrives at a certain network element, for example an AU-4 cross-connect switch, the STM-N frames are partially taken apart so that a certain information part is removed from them. In the case of a cross-connect switch, the section overhead and path overhead are removed from the STM-1 frame. However, the signal frequency does not change, so that instead of the removed information part, other information can be added in so-called free positions. The overhead parts of the frames also contain so-called growth bytes and reserved bytes, for which no specific use has yet been defined, so that in their place other information can be added to carry out the method according to the invention.

Furthermore, it is known from prior art that a signal contains certain parity information for each frame, e.g. a parity verification is calculated for the VC-4 frame in accordance with the BIP-8 procedure and this verification is placed in the overhead of the next VC-4 frame. According to the invention, a certain number of bits in a certain space of the free position is reserved and used to indicate the number of observed parity errors. When the signal arrives at a certain network element 1, its input section 4 calculates the parity of e.g. a VC-4 frame using the same eighth-order polynomial with which the original parity was calculated. Comparison of the provided parity result with the original parity information provided in the signal gives the number of parity errors for each frame before processing the frame in the network element.

For all information structures, which have a frame format and which are used for information communication in the SDH system, localization of bytes or the byte positions includes names with letter and number identification. A preferred embodiment of the invention uses the byte positions with the identifiers H3 1 in AU-4 frames, H3 in TU-3 frames and V3 in TU-2/TU-12 frames to place both information regarding the number of parity errors and test bits. The number of bits used for these purposes may vary. Use of said byte positions has a particular advantage in that no regular channel for logical information communication can be connected to them due to the fact that according to recommendations it can be used for so-called negative adjustments, which will be described in more detail below. The present invention does not require that the byte positions have a regular allocation, in other words an allocation in each frame, in order to be used in accordance with the invention, but negative adjustments can be made according to the recommendations. The byte positions are used in accordance with the invention in those frames where no negative adjustment has been carried out. The present invention thus does not limit any later additions of regular logical information communication channels. Fig. 3 shows an embodiment where the parity error information is coded in four bits PVB, and the number of test bits TB is also four. These two groups of four bits each are located one after the other so that they occupy one byte in total. Because four bits can represent the numbers 0 to 15 in the decimal system, this device can indicate a maximum of 15 observed parity errors. Four bits can indicate a maximum of 8 parity error conditions, due to the fact that in the preferred embodiment of the invention the BIP procedure, which is known per se, is used for encoding the number of errors, whereby the i'th bit of each multi-bit parity check represents the parity to every i'th bit group with parity coded information. Fig. 3 shows parity error bits and test bits PVB, TB with respect to successive VC frames, so that eight bits on the top represent a certain VC frame, the eight bits on the next row represent the next VC frame, etc. It is advantageous to change the mutual order of test bits TB and parity error bits PVB regularly due to the fact that at several points in a typical network element transmitted information is processed in parallel mode on a bus with a width equal to eight bits, and due to the fact that a purpose of using test bits to find whether each of the eight individual signal paths on the bus is working correctly. Furthermore, it is possible to determine whether a certain conductor of the bus is "jammed" to one or zero, or whether a bit on a certain conductor affects the bits on adjacent conductors when the bit pattern formed by the test bits TB alternates regularly, e.g. in a sequence 0000 - 1111- 0000 - 1111 or 0000 - 1010 - 1111 - 0101 (so that each possible bit pattern appears in turn both in the first four bit positions and in the second four bit positions).

The logical connection carried by the test bits in the network element (from the input section 4 to the output section 6 in the embodiment of Fig. 2) may be called a test channel or a pilot channel. It is possible to form several logical independent pilot channels by performing in the microprocessor 8, which controls the operation of the network elements, certain settings to certain definitions that affected the signal transmission in the network element. Fig. 4 shows an embodiment that uses two pilot channels PILOT 1 and PILOT 2.1 in addition to these, a so-called error channel E_CNT is used in accordance with the invention to send the number of observed priority errors, E_CNT forms a logical connection in the network element to send the bits representing the number of parity errors . In the embodiment of fig. 4 there are a total of eight parity error bits and test bits so that they occupy a space of one byte (bytes H3 1, H3 or V3 in the figure). The bits of the PILOT channel and the E_CNT channel, which transmit information belonging to certain successive VC frames, are shown in the figure below each other, in the same way as in fig. 3. A similar alternation of the bit positions used for other purposes to that shown in fig. 3 is used in this embodiment.

A so-called adjustment can be used when the transmission frame is formed, if the clock frequency of the formed frame is higher or lower than the clock frequency used to pack the payload at other locations on the network. A negative adjustment is used in the case where the clock frequency of the frame to be formed is lower than the clock frequency used to pack the payload and where the shift buffer used for temporary storage of sent information is subject to overflow. Then the bytes are taken from the payload and placed in the area usually reserved from AU/TU pointers. In the embodiment of fig. 4, rows 8 and 15 correspond to a situation where it was detected at the input section 4 of the network element that a negative adjustment was made in the relevant frame. Detection is based on examination of AU/TU pointers in a manner known per se. Parity error bits and test bits are not used in this frame, but the space (bytes H3 1, H3 or V3 in Fig. 4) reserved for them is used to send the information DATA to be sent. In the embodiment of fig. 4, negative adjustment is made only in random frames corresponding to rows 8 and 15. At the next frame, where no adjustment is made (in rows 9 and 16), the use of parity error bits and test bits continues from the point in the sequence where it was left before the break on due to the negative adjustment. A positive adjustment in the frame has no effect on the use of parity errors and test bits.

In another preferred embodiment of the invention, a calculated parity error information for a frame, in which a negative adjustment is made, is added to the parity error information for a next frame without negative adjustment. Thus, all frames will be examined for parity errors.

With reference to fig. 5, the microprocessor 8, which controls the operation of the network element 1, supplies the content of the pilot channels or test bits both to the input section 4 and the output section 6. The input section includes a receiver RX whose input interface corresponds to the definitions given in recommendations G.703 or G.957. Function blocks 9 and 10 are designated for interpretation of section overhead AU pointers. In connection with the interpretation of AU pointers, it is also investigated whether a negative adjustment has been made in the frames. Block 11 interprets the path overhead to the VC level, and block 12 calculates the parities relative to the VC frame processed by network element 1. Similarly, blocks 13, 14 and 15 interpret the overhead and pointers and calculate the parity of the input information for lower hierarchy levels. The parity comparison block 16 compares the parity information arriving with transmitted information with the parity information calculated by the blocks 12 and 15 and determines the number of errors found. In the addition block 17, the bits E_CNT, which represent the number of parity errors and test bits PILOT supplied by the microprocessor, are added to those frames in which no negative adjustment is performed.

The output section 6 includes identical blocks 6a and 6b, which on the information supplied by the parallel switch blocks 5a and 5b perform essentially the same addition and calculation operation as at blocks 10 to 16 in the input section (blocks 18 to 24 are shown for block 6a as an example). The logic block 25 searches the pilot channel for information supplied through the network element 1, which pilot channel must be in accordance with the test bit pattern supplied by the microprocessor, to check test bits and bits representing the number of parity errors. When the correct bit position has been found, the output section 6 monitors how test bits and parity error bits are mutually located in accordance with the sequence shown in fig. 4. The comparison block 26 compares the number of parity errors with the number indicated by parity error bits and examines whether test bits are correctly sent. A message of the interrupt type is given to the microprocessor 8 if there are errors in test bits or in the number of parity errors. The selector 27 decides either on the basis of instructions provided by the microprocessor 8 or in the course of certain condition-dependent (so-called hardware decisions) which of the blocks 5a or 5b is to be selected or determines the path through which inputs can be accepted and forwarded. Blocks 28 and 29 can add information to the overhead parts of the information to be forwarded. The last block of the output section 6 is the transmitter TX, whose interface matches that specified in recommendations G.703 or G.957.

Individually for each frame, the microprocessor 8 can prevent the search for test bits, e.g. in a situation when a protection switch has been set in the network element during a certain frame (the signal path has changed from the switch block 5a to the switch block 5b), or in some other situations where the test bit interpretations are likely to be wrong, causing an unnecessary error alarm. On the basis of error indications from the output section 6, the microprocessor 8 determines whether the signal is connected to pass through alternative switch elements 5b. The alternative function is the above-mentioned "hardware decision" in the output section 6, whereby the operation can be made faster. In the preferred embodiment, the microprocessor 8 stores information about fault situations and over-connections, and if necessary a message about them is supplied to the operator who controls the operation of the network element.

In certain special situations, the network element according to a preferred embodiment of the invention differs slightly from those described above. E.g. the network element operates during the transmission of ongoing narrowband data transfer services in so-called LOP mode (lower order path), whereby the test bits were added to sent information, but parity changes in the frame are not observed. The bits representing parity changes are then set to zero, which in normal operation represents a message that no parity errors have been found. Even then, the test bits can be used to examine the internal operation of the network element.

The method according to the invention can be used at different hierarchy levels depending on the task of the respective network element and which hierarchy level information is processed in this element. While the addition and interpretation of parity error bits and test bits has been described above only between the input and output sections of the network element, the method according to the invention can also be used so that there are several addition and/or interpretation points within the network element. This gives a higher accuracy when observing errors and operational disturbances. The effective observation area between a certain addition point and corresponding interpretation point can be consecutive with other effective observation areas, within it or partially interlaced with it. Parity error bits and test bits added in a number of addition points can be interpreted at the same interpretation points, since bits added at the same addition point can also be interpreted at a number of interpretation points. The attachment points and interpretation points can also be switched within the network element by means of software or operator intervention.

The method according to the invention provides a fast, efficient and reliable observation of transmission errors that occur within a network element. With the method, it is particularly possible to find out whether the observed errors have occurred within the relevant network element or earlier along the transmission route. Based on the information generated by this method, the microprocessor controlling the operation of the network element can choose to use the block that operates best when the network element includes redundant blocks. On the basis of information generated by the microprocessor, the section of the network element requiring service can be located quickly and reliably.

Claims (12)

1. Method for testing the operation of a network element (1) in a transmission network based on synchronous digital hierarchy where sent information is arranged in frames, characterized in that verification data is added to the sending information in a certain first section (4) of the network element (1), whereby verification data in the at least partially formed on the basis of the contents of the frames and that verification data is read into certain second sections (6) of the network element to determine whether the component between the first section (4) and the second section (6) is operating correctly in the network element (1). 2. Method according to claim 1, characterized in that the verification data includes a parity error part (PVB, E_CNT) which indicates whether a parity error in the transmission information has been detected in the first section (4). 3. Method according to claim 2, characterized in that the parity error part (PVB, E_CNT) includes quantity information, which indicates how many parity errors in the transmission information have been detected in the first section (4). 4. Method according to claim 2 or 3, characterized in that on the basis of the parity error part (PVB, E_CNT) the second section (6) examines whether the number of parity errors in the transmission information has changed between the first section (4) and the second section (6). 5. Method according to any one of the preceding claims, characterized in that the verification data includes a test part (TB; PILOT1; PILOT2), which is a predetermined string of characters. 6. Method according to any one of the preceding claims, characterized in that the string of characters is varied in accordance with a predetermined order of variation. 7. Method according to any one of the preceding claims, characterized in that the verification data parts in accordance with verification data are added at different hierarchy levels to the frame structure. 8- Method according to any one of the preceding claims, characterized in that verification data is removed from the sending information before the information is forwarded from the network element (1). 9. Method according to any one of the preceding claims, characterized in that the verification data part according to verification data is added to transmission information at several points in the network element (1). 10. Method according to any one of the preceding claims, characterized in that verification data added to the transmission information is interpreted at several points in the network element (1). 11. Transmission device (1) for transmitting information in a transmission network based on synchronous digital hierarchy, where the transmission device (1) includes a first section (4), a second section (6) and devices (5a, 5b) for sending information between them, characterized by that the first section (4) includes information generating devices (12,15, 16) for generating verification data based on the content of the transmission information that has been received, and an addition device (17) for adding verification data to transmission information and that the second section (6 ) includes an interpretation device (25, 26) for interpreting verification data to determine whether the devices (5a, 5b) for sending information between the first section (4) and the second section (6) are operating correctly. 12. Transmission device (1) according to claim 11, characterized in that the first section (4) includes a first parity calculation device (12, 15) for calculating parity data for the information it has received and a leading comparison device (16) for comparing calculated parity data with parity data contained in the received information and an adding device (17) for adding data regarding the occurrence of errors detected during the comparison with verification data and that the second section (6) includes the second parity calculation device (20, 23) for calculating parity data for the information it has received and a second comparison device (24) for comparing calculated parity data with parity data contained in received information and a third comparison device (26) for comparing data representing the occurrence of errors detected during comparison with verification data.